Technical Field of the Invention
[0001] The present invention relates to charged particle beam systems, such as focused ion
beam systems and electron beam systems.
Background of the Invention
[0002] Charged particle beams, such as focused ion beam systems and electron beam systems,
direct charged particles onto a work piece for processing the work piece or for forming
an image of the work piece. Charged particle beam systems are used, for example, in
integrated circuit fabrication and other nanotechnology processing. Charged particles
beam systems typically include a source of particles, a beam blanker, accelerating
lenses, focusing optics, and deflection optics.
[0003] A charged particle source may be, for example, a liquid metal ion source, a plasma
ion source, or a thermal field electron emitter, such as a Schottky emitter. A beam
blanker interrupts the beam by directing it away from the work piece and into a solid
stopping material.
[0004] The focusing optics focus the beam into a spot or a predefined shape on the surface
of a sample. Focusing optics typically include a combination of condenser lenses and
an objective lens. The lens can be electrostatic, magnetic, or various combinations
of the two. Charged particle lenses, like light lenses, have aberrations that prevent
the particles from being focused to a shape image. The aberration is least for charged
particles passing through the center of the lens, and the aberration increases as
the distance from the center of the lens increases. It is desirable, therefore, for
the charged particle beam to pass very near the center of the lens. One type of aberration,
referred to as "beam interaction" occurs because the particles in the beam, all having
the same electrical charge, repel each other. The closer the particles are to each
other, the greater the repulsive force. Because the particles are typically converging
after passing through the objective lens, it is desirable to position the objective
lens as close as possible to the work piece, to reduce the time that the particles
are focused in a tight beam. The distance between the objective lens and the work
piece is referred to as the "working distance."
[0005] The deflection optics direct the beam to points, referred to as "dwell points" or
"pixels," on the surface of the work piece. For example, the beam may be directed
in a raster pattern, in a serpentine pattern, or toward an arbitrary sequence of individual
points. The beam will typically dwell at a point for a specified period, referred
to as "dwell period," to deliver a specified "dose" of charged particles, and then
be deflected to the next dwell point. The duration of the dwell period is referred
to as the "dwell time" or the "pixel rate." (While pixel "rate" more properly refers
to the number of pixels scanned per second, the term is also used to indicate the
time the beam remains at each pixel.)
[0006] The deflection optics can be magnetic or electrostatic. In focused ion beam systems,
the deflection optics are typically electrostatic. Electrostatic deflectors for focused
ion beam are typically octupoles, that is, each deflector includes eight plates, distributed
around the circumference of a circle. Different voltages are applied to the eight
plates to deflect the beam away from the optical axis in different directions.
[0007] If the deflector is placed below the objective lens, the beam can pass through the
center of the objective lens to minimize aberration. Such a configuration is used,
for example, in the VisION System sold by FEI Company, the assignee of the present
invention. Placing the deflector below the objective lens, however, increases the
working distance, thereby increasing the beam aberration.
[0008] To minimize the working distance, one can place the deflector above the objective
lens. With the deflector above the lens, however, when the beam is deflected, it is
moved away from the center of the lens, thereby increasing certain aberrations. To
solve this problem, many focused ion beam systems use a two stage deflector 100 as
shown in FIG. 1 to deflect a beam 102 from an optical axis 104. A first stage 110
deflects the beam 102 to one side of optical axis 104, and the second deflector 114
deflects the beam back to the other side of optical axis 104 so that the beam 102
passes through the center of an objective lens 120, but at an angle such that the
beam is deflected to be in the correct position as it impacts a work piece 122. Voltages
of the same magnitude are typically applied to both stages of the deflector to achieve
the desired deflection.
[0009] Charged particle beams process or image work pieces by delivering a calculated number
of particles to precise locations on the work piece. Each particle causes a change
in the work piece and the ejection of secondary particles. To precisely control the
processing, one must control the number of particles impacting each point on the surface.
As features of the work pieces processed by charged particle beams get ever smaller,
charged particle beams must be able to more precisely deliver a controlled number
of ions to each small point on the work piece surface. This precise control requires
deflectors that can rapidly move a beam from pixel to pixel, while delivering the
correct dose of particles to each pixel.
Summary of the Invention
[0010] An object of the invention is to improve the ability of charged particle beam systems
to precisely direct particles to a work piece.
[0011] As the demands for precision in charged particle beam processing increases, the time
required for charged particles to move through the charged particle beam system becomes
a significant factor in precisely controlling the beam. For example, when a signal
applied to a deflector system is changed to direct the beam from a first dwell point
to a second dwell point, charged particles that have already passed through part of
the deflection system when the voltage is changed will not receive the correct forces
to deflect them to either the first or the second dwell point. As dwell periods become
shorter, voltage changes become more frequent, and the number of particles that are
traversing the deflection system during voltages change increases, so more particles
are misdirected, making it impossible to precisely process a work piece.
[0012] The invention compensates for the time required for the charged particles to traverse
the system by altering one or more of the deflector signals. According to one embodiment
of the invention, signals applied to the stages of a multiple stage deflector system
are applied independently, for example, at different times, to more closely align
the deflection signals with the flight of the particles through the deflection system
so fewer particles are misdirected. For example, in a two stage deflection system,
a change to the second stage deflector voltage may be delayed with respect to the
change to the first stage deflector voltage. The delay provides improved beam control
and allows for precise processing even at reduced dwell time.
Brief Description of the Drawings
[0013] For a more thorough understanding of the present invention, and advantages thereof,
reference is now made to the following descriptions taken in conjunction with the
accompanying drawings, in which:
[0014] FIG. 1 shows a typical two stage deflector for a focused ion beam system.
[0015] FIG. 2 shows a two stage deflector used to model the effect on deflection of the
time of flight of the ions through the deflector.
[0016] FIG. 3 shows distances and time delays in a typical focused ion beam column from
the blanking plates to the work piece.
[0017] FIG. 4 shows the actual charged particle deflection determined by a simulation where
the pixel rate is 300 ns and there is no delay in applying the deflection signals
to the two stages.
[0018] FIG. 5 shows the actual charged particle deflection determined by a simulation where
the pixel rate is 300 ns and the second stage deflection signal is delayed 105 ns
in accordance with an embodiment of the invention.
[0019] FIG. 6 shows the actual charged particle deflection determined by a simulation where
the pixel rate is 130 ns and the second stage deflection signal is delayed 105 ns
in accordance with an embodiment of the invention.
[0020] FIG. 7 shows the actual charged particle deflection determined by a simulation where
the pixel rate is 90 ns and the second stage deflection signal is delayed 105 ns in
accordance with an embodiment of the invention.
[0021] FIG. 8 shows the result of focused ion beam etching using a 200 ns pixel rate and
no delay between the first stage and second stage deflector signals.
[0022] FIG. 9 shows the result of focused ion beam etching using a 200 ns pixel rate with
a delay applied between the first stage and second stage deflector signals.
[0023] FIG. 10 shows the result of focused ion beam etching using a 100 ns pixel rate and
no delay between the first stage and second stage deflector signals.
[0024] FIG. 11 shows the result of focused ion beam etching using a 100 ns pixel rate with
a delay between the first stage and second stage deflector signals.
[0025] FIG. 12 shows a preferred method in accordance with the invention.
Detailed Description of Preferred Embodiments
[0026] The invention facilitates precise delivery of charged particles in a charged particle
beam system having a directable beam, and is particularly useful when the system is
changing the beam position rapidly, that is, when using short dwell times.
[0027] In a typical high performance charged particle beam optical column, a dual stage
deflection system is used to control the position of the particle beam on the work
piece. Each stage of the deflection system imparts an appropriate deflection to the
beam as it passes. The two stages work together to ensure the beam follows the correct
path through the column and the particles impact the work piece at the desired point.
The amount of deflection in each stage is determined by electrical signals that apply
voltages to the deflector plates in that stage. By varying the voltages on the plates,
the electrical fields through which the charged particles pass are varied, which changes
the force on the particles and therefore their landing positions on the work piece.
[0028] In a prior art deflection system, the beam is moved to a different pixel by changing
the voltages on both deflection stages at the same time. However, because it takes
the particles a finite amount of time to pass through the deflection system, there
will be particles within the system while the voltage change is occurring. Those particles
will receive part of the deflection force appropriate for one pixel and part of the
deflection appropriate for the next pixel. Because of the criss-cross design of the
two stage deflector, the particles passing through the deflection system during the
transition will typically impact not at a point between the two pixels, but at some
other point.
[0029] For example, particles that have already passed through the first deflector stage
when the voltages are changed will not be affected by the changed first deflector
stage voltage. Rather, they are affected only by the second stage voltage change.
These particles will land on the workpiece at an undetermined point that is neither
the original point nor the final point. Some points on the work piece will not receive
the full particle dose intended, while other points may receive an excess of particles.
The effects of this phenomenon become more pronounced as the dwell time becomes closer
to the time it takes a particle to pass through the deflection system, because as
the dwell time gets shorter, a higher percentage of the charged particles are affected
by the transition. When the dwell period is less than the time required for the particles
to traverse the deflection system, none of the charged particles will receive the
intended deflection force.
[0030] In accordance with a preferred embodiment of the invention, this misdirection effect
of charged particles in the system during the signal change is be mitigated by altering
the deflector signals. The deflector signals in any deflector stage can be varied.
For example, in a two stage deflector, the alteration can include introducing a delay
in the electrical signal going to the second deflector stage. The signal is first
changed for the first stage and then, at a later time, the signal is changed for the
second stage. This time delay can be varied for different implementations, but the
amount of delay is typically related to how long it takes the charged particle to
travel through the different parts of the deflector system.
[0031] To determine the effect of the time of flight and different signal delays on the
particle landing position for systems, a focused ion beam system was modeled and various
simulations were performed.
[0032] In one embodiment of an ion beam system, applicants delayed the second stage signal
for each dwell point by the time of flight ("TOF") between the center of each deflector
octupole. For example, if the distance between octupole centers is 100 mm and the
speed of the ions is 0.25 mm/ns the signal to the lower octupole is delayed 400 ns
from the time the signal is applied to the upper octupole. The optimum signal delay
depends on the TOF, which depends on the velocity of the particles and therefore on
the accelerating voltage, which corresponds to the beam energy. The signal delay is
preferably programmable so that it can be adjusted as the beam energy is changed.
[0033] There is also some transition time required for the system electronics to change
the voltage on the plates of the octupoles, and the beam moves in a non-linear fashion
during the system electronics transition time. In preferred embodiments, the transition
is made as short as possible. The simulations described below show the short time
period of non-linear behavior, although the behavior is actually not as bad in a real
system.
Simulation Model
[0034] A simplified two dimensional, planar model of a deflection system for an ion beam
system was created using the charged particle simulation software Simion 7.0 (ion
Source Software) from Scientific Instrument Services, Inc., Ringoes, NJ. FIG. 2 shows
a deflection system 200 that was modeled. Deflection system 200 includes an upper
octupole 202 and a lower octupole 204, separated by a spacer 206. FIG. 2 also shows
an upper octupole termination plate 210 and a first element 212 of a second ion lens.
The first element of the second ion lens 212 serves as a field termination element
for the lower octupole 204 to provide a more realistic axial deflection field. (The
first ion lens is position above the deflection system 200 and is not shown or modeled).
All components are centered on an optical axis 220.
[0035] FIG. 3 shows a schematic of the ion beam column that was modeled in FIG. 2. Blanking
plates 312 are positioned above upper octupole 202. A termination plane 308 is added
at a typical working distance 310 of 15 mm below lens 212. This lens configuration
allows the comparison of deflected ion positions as a function of time Simulated groups
of 400 to 1000 ions were launched on an optical axis 220, each ion separated by a
1 ns delay. This provides a stream of ions similar to a continuous beam. Ions launched
at different times are in different parts of the column when the deflection voltages
changes. A user program was written in Simion's programming language to modulate the
voltages on the octupole plates in real time as the ions are in flight through the
model. Simion's recording features were used to record the ion's time and radial position
at the 'sample plane', as well as more detailed information on the nanosecond-by-nanosecond
position and local electrostatic fields of each ion in the model. This data was then
imported into Mathematica 4.1, from Wolfram Research, Champaign, IL, using a notebook
designed to import, parse, and plot the data for a more automated analysis.
[0036] The model simulated 30 keV gallium ions, which traveled at about 0.29 mm/ns. The
scale to the right in FIG. 3 shows the column dimensions, and the scale to the left
shows the corresponding times for the gallium ion to travel those dimension. FIG.
3 shows that blanking plates 312 have a length 340 of about 10 mm. The distance 342
from the top of blanking plate 312 to the top of upper octupole 202 is 49 mm. The
length 344 of upper octupole 202 is 16 mm and the length 346 of lower octupole 204
is 36 mm. The spacing 348 between upper octupole 202 and lower octupole 202 is 15
mm. The distance 350 from the top of upper octupole 202 to the bottom of lower octupole
346 is about 68 mm.
[0037] For a 30 keV gallium ion beam, the time, tb, required for an ion to travel from the
bottom of the blanking plates to the upper octopole is 134 ns. The time, tu, required
for a gallium ion to travel through the upper octupole is 56 ns. The time, tg, required
for a gallium ion to traverse the distance between the octupoles is 53 ns, and the
time, tl, required for an ion to traverse the lower octupole is 125 ns. The time,
tf, for an ion to go from the center of the upper octupole to the center of the lower
octupole is about 143 ns. The total time for an ion to traverse the deflector assembly
is tu + tg + tl, or about 234 ns. In addition to the time of flight delay, one must
also consider the system electronics transition time of about 10 ns to change the
voltage on the deflectors, and so one can consider the total time required to redirect
the beam and have ions land on the desired new spot to be about 245 ns.
[0038] The octupole dimensions and positions were set so that the beam passes through the
center of lens 212, and lower octupole creates the maximum field of view, deflecting
the beam, for example, an extra 500 µm to achieve a I mm field of view. If a lower
energy beam is used, the TOF is increased. For example, a 5 kv beam increases the
TOF by 2.45 and the delay between centers of the octupoles would be 318 ns.
Simulation Results
[0039] The simulation results are discussed in three sections below: deflection without
delay, deflection with delay (including optimal delay setting and rapid deflection),
and blanking. All simulation used Ga+ ions with an atomic mass of 69.7AMU and a kinetic
energy of 30 keV. Commonly used gallium liquid metal ion sources are a mixture of
more than one isotope, and the deflections and the time of flight of the different
isotopes will be slightly different. One could use a single isotope gallium source
to remove this factor. Deflection voltages on the plates were stepped in 10 V increments
with each transition requiring 10 ns to complete.
[0040] The simulation moved the ion beam between four pixels. The target deflections at
four voltages were computed as shown in Table 1:
Plate Voltage on octupoles (V) |
Net Deflection (mm) |
+/- 185 |
0.855 |
+/- 175 |
0.808 |
+/- 165 |
0.761 |
+/- 155 |
0.715 |
Table 1
[0041] Voltages of the same magnitudes are applied to both stages of the deflection, and
the polarity of the plates are reversed in the first and second stages. To position
the ion beam at the first pixel, which is 0.855 mm from the optical axis 220, a voltage
of +/-185 V is applied to the upper octupole and the lower octupole. To deflect the
beam to the second pixel, 0.808 mm from the optical axis, +/- 175 V is applied to
the upper and lower octupoles. The upper octupole is oriented such that its deflection
is in the negative y direction. The lower octupole is oriented the opposite manner
such that its deflection is in the positive y direction.
[0042] As described earlier, the ions were "flown" as a single group, with each ion in the
group has a 1 ns delay relative to the preceding ion. In the graphs of FIGS. 4-7,
the x-axis represents the ion's delay time relative to the start time of the first
ion.
Deflection Without Delay (Prior Art)
[0043] The simulation shows that operating the column in a deflection mode in which the
voltages on the plates of the upper and lower octupole are changed simultaneously
provides less precise beam positioning than operating with a delay between voltage
changes on the octupole. An ion will arrive at the sample plane with the desired deflection
only if it has experienced the full deflection fields in the upper and lower octupoles.
Any ion that is inside the deflection system, from the beginning of the upper octupole
to the end of the lower octupole, when the deflection voltage changes will be misdirected
because it will be subjected to unmatched fields in the upper and lower octupoles.
[0044] It takes about 245 ns for a 30 keV gallium ion beam to fully transition from one
pixel to another, including 235 ns time of flight through the deflectors, as shown
in FIG. 3, and 10 ns to change the deflector voltage. For a dwell time of 300 ns,
for example, the ions see unmatched transitions voltages during 245 ns and receive
the correct voltage during only 55 ns. Even if the system electronics delay were eliminated,
the minimum time for a pixel-to-pixel transition on the sample plane is just under
245 ns.
[0045] FIG. 4 shows a plot of ions simulated in a no-delay deflection system having a pixel
time of 300 ns and in which the signals are changed simultaneously in both deflection
stages. The x-axis represents the time from the beginning of the simulator that an
ion was launched and the y-axis shows the calculated deflection of the ion. The target
deflection of the first set of ions, which see the full +/-185 V deflection voltages
in both octupoles, is 0.855 mm as shown in Table 1. The target deflection of the second
set of ions is 0.808 mm, with +/-175V applied to the octupoles. In the simulation,
the ions begin with a deflection voltage of +/-185V applied to the octupoles, and
then the deflection voltage is changed to +/- 75V for 300 ns. The octupole voltage
is changed periodically at the pixel rate. During most of the dwell period, the ions
do not land at the first or the second target pixel location. The plot in FIG. 4 can
be divided into five regions for analysis.
[0046] Region A. These ions, being the first launched traveled through the entire assembly
before the voltages were changed. These ions are subject to the correct +/- 185V through
both octupoles and are deflected 0.855 mm as required.
[0047] Region B. The ions represented in this region of the plot were inside the lower octupole
when the voltages were changed. lons started later in the simulation, that is, those
higher up in the lower octupole when the voltage changes, experienced a greater period
of reduced deflection potential (175 V vs. 185 V) in the lower octupole.
[0048] Region C. Ions in this group were in the spacing or gap between the upper and lower
octupoles when the voltages were changed. While these ions were subject to unbalanced
deflection voltages, they all experienced the same deflection in the upper and in
the lower octupoles.
[0049] Region D. These ions were in the upper octupole at the time of the voltage change.
Those with later launch times were higher up in the octupole and therefore experienced
the correct voltage for a longer time and are, therefore, deflected closer to the
target deflection.
[0050] Region E. These ions were above the upper octupole at the time of the voltage change,
and therefore were subjected to only the stable deflection voltages of +/- 175 V in
the upper and lower octupoles. These ions are properly deflected 0.808 mm from the
optical axis.
[0051] In Fig. 4, the unstable deflection transition period begins with ions launched at
about 55 ns from beginning of the simulation and ends with ion launched at about 300
ns. The total time required to reposition the beam from one pixel to the next, therefore,
took about 300 ns - 55 ns = 245 ns, which is the total transit time of the deflection
system. Thus, regardless of the speed of the deflection electronics, the fastest pixel-to-pixel
transition at 30 keV in the ion column without a lower octupole signal delay is about
245 ns. More generally, the fastest pixel-to-pixel transition that can be achieved
in any ion column employing a similar deflection subsystem and lacking a deflection
delay is equal to the transition time of the ions through the deflection subsystem.
[0052] The actual pixel dwell time (T
actual), that is, the time during which the beam is delivering ions to the intended position
on the work piece, is equal to the programmed, intended dwell time (T
programmed dwell time) minus the pixel transition time (T
pixel transition) of the deflection system.
[0053]
[0054] Therefore, if the ion column deflection system described above is driven at a pixel
rate of 300 ns with 30 keV Ga+ ions, the actual dwell time per pixel is 300 ns - 245
ns = 55 ns. This difference between the actual dwell time and the programmed dwell
time is significant when attempting to calculate the dose per pixel of a scanning
ion beam. Each pixel will received less ions than intended during its programmed pixel
time, and may received an unknown number of misdirected ions when the beam is intended
to be positioned elsewhere.
Deflection with Delay
[0055] By delaying application of the signal to the lower octupole until after the upper
octupole signal has changed, the number of misdirected ions can be reduced. In some
embodiments, rather than having to wait after a signal change for all ions in the
deflection system to clear the deflector before subsequent ions are properly directed,
only ions in about half the system need to exit before subsequent ions are properly
directed.
[0056] There are many possible approaches to implementing a deflection delay in the ion
column, and two examples are provided below. The preferred method for a specific implementation
will depend on how the system user interface and beam scanning software are structured.
The invention is not limited to any particular signal alteration, and skilled persons
will be able to determine appropriate signals using the information provided herein
as examples and guidance. Other aspects of the deflection system, such as the physical
dimensions and positions of the components can be optimized for specific implementations.
[0057] In a first example based on the ion column model of FIG. 3, the voltages in the upper
octupole begin to change at t = 0 ns and finish changing at t = 10 ns. The first ion
subjected to the changed upper octupole deflection fields over its entire path through
the upper octupole will arrive at the lower octupole at t = 10 ns + 56 ns + 53 ns
= 119 ns, which represents the time required for the upper octupoles to finish modulating,
the time required for an ion to travel through the upper octupole, and the time required
for the ion to travel through the octupole gap. This duration is referred to as the
"upper octupole transition time." 119 ns is an approximation because of field leakage
into different parts of the 'field-free' regions.
[0058] In the first example, the delay for applying a pixel signal to the lower octupole
is equal to the upper octupole transition time to allow the first ions of a new pixel
to arrive at the lower octupole before changing its potentials. This allows some,
but not all, of the last ions of the previous pixel to be properly deflected by the
lower octupole before the voltage is changed. This embodiment, therefore, ensures
that the new pixel starts on time, that is, the first ions directed to a new pixel
are properly directed, and sacrifices the last ions of the preceding pixel. In the
first example, the voltage to the lower octupole is changed about 119 ns after changing
voltage on the upper octupole. After calculating a delay time, the delay is set to
approximately the delay time, that is, within about +/- 30 % of the calculated value,
and the delay time can be optimized experimentally.
[0059] In a second example, the delay on the lower octupole is set to allow all the ions
from the previous pixel to exit the lower octupole before modulating its voltages.
While allowing the previous pixel to finish, the first ions of the next pixel are
mis-deflected. Applying this example to the column model in FIG. 3, the time for ions
to travel from the exit of the upper octupole to the exit of the lower octupole is
53 ns + 125 ns = 178 ns. The time is referred to as the "lower octupole delay time."
[0060] The net effect of the two examples is the same -- a pixel transition time of about
130 ns as opposed to a transition time of 245 ns for the non-delay case. The difference
between the embodiments described above is that the pixel transition occurs when the
ions are at different positions within the deflection system, i.e., the transition
occurs either at the end of one pixel or at the beginning of the next.
[0061] The calculated delay can be adjusted to optimize the number of misdirected ions.
Applicants found that a delay of about 105 ns between the upper and lower octupole
signals provided the fewest misdirected ions. In this model, the transition time was
not considered part of the pixel rate, which caused the slight shift in the pixel
deflection shown in FIG. 5.
[0062] The downward trailing transition at each pixel in FIG. 5 and the subsequent upwardly
movement toward the target deflection indicates that ions are not sufficiently deflected
during part of the transition and then the ions are deflected further until the deflection
is correct. The downward trailing region represents ions from the preceding pixel
that were still in the lower octupole at the time of the transition, and the upwardly
directed region represents ions that were in the partial transition of the upper octupole
during its modulation.
[0063] In the example of in FIG. 5, with a delay of 105 ns in changing the voltage of the
lower octupole and programmed pixel duration of 300 ns, about 130 ns are required
for the pixel transition, leaving about 170 ns of actual pixel dwell time. The pixel
transition time is present regardless of pixel rate. In deciding whether to implement
a deflection delay for a specific application, both the pixel rate and the relative
percentage of the pixel dose which is misdirected in the pixel transition are considered.
[0064] The simulation results have implications for operating the ion column with very fast
deflection rates. Increasing pixel rates have the effect of reducing the width of
the plateaus at each pixel. At a pixel rate equal to the pixel transition time, the
current at each pixel is no more than the current during the transition as the beam
never stops moving. The ion dose delivered to the pixel relative to the dose during
transition decreases, which will decrease the signal-to-noise ratio of a charged particle
beam image. Essentially, the image will become less clear as the number of secondary
electrons emitted from the target pixel is decreased and secondary electrons emitted
from other areas of the work piece increase. Thus, the brightness of a point on the
image corresponds less well to properties of a point on the sample.
[0065] FIG. 6 shows the loss of pixel plateau. The plot in FIG. 6 corresponds to a pixel
rate equal of 130 ns, which is also the pixel transition time using a 105 ns delay.
As the pixel rate is increased beyond the pixel transition time, the ion deflection
pattern becomes more complex, but still regular. This can be seen in FIG. 7, in which
the deflection was operated at 90 ns pixel rate and a delay of 105 ns.
Blanker
[0066] The blanking plates 312 in the ion column of FIG. 3 are located about 39 millimeters
above the top of the upper octupole. Practically, this means that there is a relatively
long line of ions below the blanking plates which will be free to exit the column
after the rest of the beam has been blanked. There will be an additional 134 ns of
ion current in the column in addition to the 245 ns of current in the octupoles and
the 148 ns of current in lens 212 between the octupole and the sample. That makes
for a net 528 ns or so from the completion of the blanking modulation to the time
that the beam terminates at the sample plane at 30keV.
[0067] It is known to compensate for the blanking delay by adding the ions in the pipeline
to the desired dose and dwell time, and by allowing extra time at the start of a scan
to accommodate the blanking delay. A pre-blanking software routine can be used to
compensate for the drift space and to ensure that the beam is blanked at the optimum
time so that all dwell points receive close to the specified dose. The determination
of the blanking compensation becomes somewhat complicated, however, when operating
at a 100 ns dwell time, and the blanking delay is 500 ns.
Test Results
[0068] FIGS. 8-11 shows representations of samples that were subjected to focused ion beam
processing using a VislONary™ lon Column from FEI Company. The beam was programmed
to follow a serpentine pattern on the samples. For this ion column, applicants calculated
that a delay of 285 ns was appropriate between changing the first stage deflector
signal and changing the second stage deflector signal. As described above, the delay
was determined to correspond to the time of flight between the mid points of the deflectors
plus the electronics transition time.
[0069] The patterns in FIGS. 8 and 9 were formed using a pixel rate of 200 ns. The structure
in FIG. 8 was formed by the ion beam operating with no column delay, that is, the
second stage deflector signal was changed at the same time as the first stage deflector
signal. The pattern in FIG. 9 was formed with a delay of 275 ns, that is, the second
stage deflector signal was changed 275 ns after the first stage deflector was changed.
FIG. 8 shows that the beam deviated significantly from the programmed pattern. FIG.
9 shows that with the delay, the beam path much more closely approximates the desired
serpentine path.
[0070] The structures shown in FIGS. 10 and 11 were formed with a pixel rate of 100 ns.
The structure in FIG. 10 was formed by the ion beam operating with no column delay.
The structure in FIG. 11 was formed with a delay of 275 ns. Because the pixel rate
was much shorter than the transition time, which was about 550 ns, the effect of the
transition time is greater.
[0071] FIG. 10 shows that the deviation of the beam from the squared-edged serpentine pattern
is greater than the deviation in FIG. 8. FIG. 11 shows that applying the 275 ns delay
greatly improves the beam pattern compared to FIG. 10, but because of the short pixel
rate, even with a delay, the beam pattern deviates somewhat from the programmed square-edged
serpentine pattern.
[0072] FIG. 12 shows a preferred procedure for implementing an embodiment of the invention.
In step 1202, the distance between the column components, including the blanker and
the deflectors, are determined. In step 1204, the speed of the particles in the column
is determined. The speed will depend on the mass of the particles and the accelerating
voltage, and the speed corresponds to the particle energy. Once the speed of the particles
and the distances are determined, the time of flight can be determined in step 1206.
From the time of flight, an approximate delay is determined in step 1208 using, for
example, one of the methods described above. For example, the delay may be based on
the sum of the electronic delay, and the TOF in the upper octupole and the gap between
the octupoles. As another example, the delay may be based on the TOF in the gap and
the lower octupole. In optional step 1210, the delay is optimized through testing.
Once the delay is determined, the work piece is processed in step 1212. Skilled persons
will recognize that the charged particles may undergo acceleration between the blanker
and the deflector, and the time of flight is determined based upon the speed through
the deflectors.
[0073] Operating the deflection system without a delay between the upper and lower octupoles
will result in a 'pixel transition time' equal to the transit time of an ion through
the entire deflection subsystem. This pixel transition time depends on the speed and
type of the charged particles and on the length of the deflection system, so the pixel
transition time is constant in a charged particle system for a given particle specie
and energy. With the implementation of a deflection delay, that pixel transition time
can be reduced to the transit time of an ion through roughly one-half of the deflection
system.
[0074] Since the time of flight depends upon the mass of the charged particle and its energy,
a preferred charged particle beam system used to practice the invention provides an
adjustable signal delay, so that the signal delay can be varied depending upon the
charged particle beam species and energy. For example, in a gallium focused ion beam
system, one could use an ion source that contains a mixture of gallium isotopes, or,
one could use a source composed primarily of a single gallium isotope. The beam energy
used with a single ion source can be varied, with higher energies used for milling
and lower energies for imaging. The invention can improve both the accuracy of micromachining
and charged particle beam assisted deposition, as well as improving imaging.
[0075] There are a number of ways to implement such a deflection delay. The preferred implementation
will depend on other factors in the column electronics and operating software.
[0076] The model and embodiments described above provide examples of the invention applied
to a gallium focused ion beam system. The invention is applicable to any charged particle
beam system. The invention is not limited to a two stage deflector. For example, the
blanker delay can be compensated in a single stage deflector. The invention is useful
with any components of a charged particle beam system in which the separation of components
that control the beam in response to electronic signals affects the beam control because
of the time of flight between the components.
[0077] The invention could also be useful in electron beam systems. Because electrons typically
traverse through an electron beam system at speeds much higher than those of ions
in a focused ion beam system, deflection based beam control problems are not limiting
in current electron beam systems, but as specifications get tighter, particularly
for low energy beams, the invention could be useful in electron beam systems.
[0078] Although the present invention and its advantages have been described in detail,
it should be understood that various changes, substitutions and alterations can be
made herein without departing from the spirit and scope of the invention as defined
by the appended claims. Moreover, the scope of the present application is not intended
to be limited to the particular embodiments of the process, machine, manufacture,
composition of matter, means, methods and steps described in the specification. As
one of ordinary skill in the art will readily appreciate from the disclosure of the
present invention, processes, machines, manufacture, compositions of matter, means,
methods, or steps, presently existing or later to be developed that perform substantially
the same function or achieve substantially the same result as the corresponding embodiments
described herein may be utilized according to the present invention.
Accordingly, the appended claims are intended to include within their scope such processes,
machines, manufacture, compositions of matter, means, methods, or steps.
1. A method of directing charged particle beams in a charged particle beam system, comprising:
applying a first deflection signal to a first stage deflector, the first deflection
signal corresponding to a first dwell point; and
applying a second signal to a second stage deflector, the second deflection signal
corresponding to the first dwell point;
characterized by the second signal being delayed with respect to the first deflection signal.
2. The method of claim 1 in which the delay is determined at least in part by the time
of flight of a particle in the beam between different points in the charged particle
beam system.
3. The method of claim 1 in which the delay is approximately equal to the transition
time of the electronics plus the time required for a charged particle to pass from
the beginning of the first deflection electrode to the beginning of the second deflector
electrode.
4. The method of claim 1 in which the delay is approximately equal to the transition
time of the electronics plus the time required for a charged particle to pass from
the exit of the first deflector stage to the exit of the second deflector stage.
5. The method of claim 1 in which the delay is approximately equal to the transition
time of the electronics plus the time required for a charged particle to pass from
the center of the first deflector stage to the center of the second deflector stage.
6. The method of claim 1 in which the delay is determined to increase the actual time
during which the beam impacts on the pixels to which it is directed.
7. The method of claim 1 in which the delay is programmed to a value between 0 and three
times the pixel time.
8. The method of claim 7 between one half and three halves the pixel rate.
9. The method of claim 1 in which the delay is determined so as to maximize the actual
dwell time at each pixel.
10. The method of claim 1 further comprising applying a third signal to a third stage
deflector, the third deflection signal corresponding to the first dwell point and
being delayed with respect to the second deflection signal.
11. The method of claim 1 further comprising applying one or more additional deflection
signal to one or more additional deflectors.
12. The method of claim 1 in which the charged particle beam is a focused ion beam.
13. The method of claim 1 in which the charged particle beam is an electron beam.
14. The method of claim 1 further comprising applying a blanking signal to a blanking
electrode and incorporating into the deflector signals a delay caused by the ion travel
time from blanker to the deflector.
15. A charged particle beam system comprising:
a source of particles;
a first stage charged particle deflector;
a second stage charged particle deflector;
a voltage source for applying a signals to the first and second stage deflectors,
characterized in that the system is programmed to apply the second stage detector signal corresponding
to a first dwell point at a different time than the first stage deflector signal for
the same dwell point.
16. The apparatus of claim 15 further comprising a memory storing computer instructions,
the instructions including a program controlling the voltage source.
17. The apparatus of claim 16 in which the memory stores computer instructions to delay
the application of the second stage deflector signal by an amount corresponding to
the time of flight of a charged particle through a part of the system.